High-Range and High-Linearity 2D Angle Measurement System for a Fast Steering Mirror

Du, Boshi; Lv, Yong; Liu, Lishuang; Liu, Yang

doi:10.3390/s23229192

Sensors

2023

DOI: 10.3390/s23229192

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High-Range and High-Linearity 2D Angle Measurement System for a Fast Steering Mirror

Boshi Du,

Yong Lv,

Lishuang Liu

et al.

Abstract: In order to solve the problem of the insufficient range of the traditional fast mirror (FSM) angle measurement system in practical applications, a 2D large-angle FSM photoelectric angle measurement system based on the principle of diffuse reflection is proposed. A mathematical model of the angle measurement system is established by combining the physical properties of the diffuse reflecting plate, such as the rotation angle, rotation center, rotation radius, reflection coefficient and the radius of the diffuse… Show more

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2024

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Cited by 2 publications

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Modeling analysis and error correction of dynamic angle measurement based on grating shear interferometry

Li,

Xu,

Gao

et al. 2024

Opt. Express

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This paper analyzes the principle of dynamic angle measurement using grating shearing interferometry (GSI), and derives a mathematical model for angle measurement and its maximum angular velocity limit. The study identifies that the increase in measurement error with the measurement angle in GSI systems is due to aberrations, which distort the period, position, and shape of the interference fringes. The source of measurement error is thus attributed to these aberrations. To address this issue, the paper proposes a method that uses the one-dimensional square-wave phase grating as diffractive beamsplitters and optimizes the system’s parameters. Simulation results demonstrated that this method corrects aberrations within a ± 20 mrad field of view (FOV) to the diffraction limit, thereby eliminating the aberration-induced measurement error. Experimental validation was performed using a fast steering mirror (FSM). When the angle of FSM is within ±10 mrad and its angular velocity is below 4.72 rad/s, the angular error of the optimized GSI measurement system can be within ±6µrad, and the measurement uncertainty is only 0.14 µrad. This method effectively addresses the problem of increasing GSI measurement error with angle, enabling high-precision dynamic angle measurement.

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Modeling analysis and error correction of dynamic angle measurement based on grating shear interferometry

Li,

Xu,

Gao

et al. 2024

Opt. Express

View full text Add to dashboard Cite

show abstract

High-precision and large-range deflection of light beams with fast steering mirrors

Mei,

Huang,

Fang

et al. 2024

Opt. Lett.

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Fast steering mirrors (FSMs) offer a potential alternative for large-range deflection of light beams. However, for a large-stroke FSM, its pointing precision is unacceptably deteriorated due to the actuator non-uniformity, mechanical axis coupling, and the coupling of line-of-sight (LOS) kinematics. This Letter proposes a comprehensive beam-pointing algorithm by decoupling the LOS kinematic model and establishing a two-dimensional correction mapping to compensate for the non-uniformity and mechanical coupling. Moreover, the incident angle is calibrated by a non-contact method to construct the LOS kinematic model accurately. The experimental results proved that the beam-pointing accuracy can achieve a sub-milliradian level within the square field of regard (FOR) of ±25° horizontally and ±14° vertically. A pointing error of 0.87 mrad can be guaranteed within the horizontal range of −30° to 36° and the vertical range of ±24°. Therefore, the proposed method can achieve high-precision beam pointing in a large FOR and contributes to the miniaturization of optical systems.

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High-Range and High-Linearity 2D Angle Measurement System for a Fast Steering Mirror

Cited by 2 publications

References 20 publications

Modeling analysis and error correction of dynamic angle measurement based on grating shear interferometry

Modeling analysis and error correction of dynamic angle measurement based on grating shear interferometry

High-precision and large-range deflection of light beams with fast steering mirrors

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